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Autore principale: Danielski, Aleksander
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2407.14715
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author Danielski, Aleksander
author_facet Danielski, Aleksander
contents The flow of an ideal fluid possesses a remarkable property: despite limited regularity of the velocity field, its particle trajectories are analytic curves. In our previous work, this fact was used to introduce the structure of an analytic Banach manifold in the set of 2D stationary flows having no stagnation points. The main feature of our description was to regard the stationary flow as a collection of its analytic flow lines, parameterized non-analytically by values of the stream function $ψ$. In this work, we adapt this description to the case of 2D stationary flows which have a single elliptic stagnation point. Namely, we consider flows in a domain bounded by the graph of analytic function $ρ= b(φ)$, where $(ρ,φ)$ are polar coordinates centred at the origin. The position $p$ of the stagnation point is an unknown and must be included in the solution. In polar coordinates $(r,θ)$ centred at $p$, the flow lines are described by graphs of $r=a(ψ,θ)$, where $a$ is a `partially-analytic' function (analytic in $θ$, of finite regularity in $ψ$). The equation of stationary flow $Δψ= F(ψ)$ is transformed to the quasilinear elliptic equation $Ξ(a) = F(ψ)$ for the flow lines. The analysis is complicated by the fact that the ellipticity of $Ξ$ degenerates at the stagnation point. We introduce function spaces for the partially-analytic family of flow lines, modelled on the weighted Kondratev spaces, appropriate for the degenerate setting. The equation of stationary flow is thus regarded as an analytic operator equation in complex Banach spaces, with local solution given by the implicit function theorem. In particular, we show that near the circular flow of constant vorticity, the equation has unique solution $p, a(ψ,θ)$ depending analytically on parameters $b(φ)$ and $F(ψ)$.
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institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Analytic Structure of Stationary Flows of an Ideal Fluid with a Stagnation Point
Danielski, Aleksander
Analysis of PDEs
The flow of an ideal fluid possesses a remarkable property: despite limited regularity of the velocity field, its particle trajectories are analytic curves. In our previous work, this fact was used to introduce the structure of an analytic Banach manifold in the set of 2D stationary flows having no stagnation points. The main feature of our description was to regard the stationary flow as a collection of its analytic flow lines, parameterized non-analytically by values of the stream function $ψ$. In this work, we adapt this description to the case of 2D stationary flows which have a single elliptic stagnation point. Namely, we consider flows in a domain bounded by the graph of analytic function $ρ= b(φ)$, where $(ρ,φ)$ are polar coordinates centred at the origin. The position $p$ of the stagnation point is an unknown and must be included in the solution. In polar coordinates $(r,θ)$ centred at $p$, the flow lines are described by graphs of $r=a(ψ,θ)$, where $a$ is a `partially-analytic' function (analytic in $θ$, of finite regularity in $ψ$). The equation of stationary flow $Δψ= F(ψ)$ is transformed to the quasilinear elliptic equation $Ξ(a) = F(ψ)$ for the flow lines. The analysis is complicated by the fact that the ellipticity of $Ξ$ degenerates at the stagnation point. We introduce function spaces for the partially-analytic family of flow lines, modelled on the weighted Kondratev spaces, appropriate for the degenerate setting. The equation of stationary flow is thus regarded as an analytic operator equation in complex Banach spaces, with local solution given by the implicit function theorem. In particular, we show that near the circular flow of constant vorticity, the equation has unique solution $p, a(ψ,θ)$ depending analytically on parameters $b(φ)$ and $F(ψ)$.
title Analytic Structure of Stationary Flows of an Ideal Fluid with a Stagnation Point
topic Analysis of PDEs
url https://arxiv.org/abs/2407.14715